Cytotoxic activity of the amphibian ribonucleases onconase and r-amphinase on tumor cells from B cell lymphoproliferative disorders.

Although major advancements in antitumor treatment have been observed, several B cell-derived malignancies still remain incurable. A promising approach that involves targeting RNA either by the use of specific antisense oligonucleotides or cytostatic/cytotoxic ribonucleases (RNases) is being promoted. Two amphibian RNases, onconase (ONC; ranpirnase) and, more recently, r-amphinase (r-Amph), have already been tested, but thus far, mostly on solid tumors. In this study, for the first time we provide comprehensive data on ex vivo and in vivo cytotoxic activity of ONC or r-Amph against cancer cells from different B cell lymphoid malignancies, together with their detailed mode of antitumor action. Our data revealed strong pro-apoptotic activity of ONC and r-Amph in both chronic lymphocytic leukemia and aggressive B cell lymphomas, with less impact on acute lymphoblastic leukemia or multiple myeloma cells. Moreover, the antitumor action of ONC and r-Amph was markedly selective against neoplastic cells sparing normal, healthy control­derived lymphocytes.

Ribonucleases as potential modalities in anticancer therapy.

Antitumor ribonucleases are small (10-28 kDa) basic proteins. They were found among members of both, ribonuclease A and T1 superfamilies. Their cytotoxic properties are conferred by enzymatic activity, i.e., the ability to catalyze cleavages of phosphodiester bonds in RNA. They bind to negatively charged cell membrane, enter cells by endocytosis and translocate to cytosol where they evade mammalian protein ribonuclease inhibitor and degrade RNA. Here, we discuss structures, functions and mechanisms of antitumor activity of several cytotoxic ribonucleases with particular emphasis to the amphibian Onconase, the only enzyme of this class that reached clinical trials. Onconase is the smallest, very stable, less catalytically efficient and more cytotoxic than most RNase A homologues. Its cytostatic, cytotoxic and anticancer effects were extensively studied. It targets tRNA, rRNA, mRNA as well as the non-coding RNA (microRNAs). Numerous cancer lines are sensitive to Onconase; their treatment with 10-100 nM enzyme leads to suppression of cell cycle progression, predominantly through G(1), followed by apoptosis or cell senescence. Onconase also has anticancer properties in animal models. Many effects of this enzyme are consistent with the microRNAs, one of its critical targets. Onconase sensitizes cells to a variety of anticancer modalities and this property is of particular interest, suggesting its application as an adjunct to chemotherapy or radiotherapy in treatment of different tumors. Cytotoxic RNases as exemplified by Onconase represent a new class of antitumor agents, with an entirely different mechanism of action than the drugs currently used in the clinic. Further studies on animal models including human tumors grafted on severe combined immunodefficient (SCID) mice and clinical trials are needed to explore clinical potential of cytotoxic RNases.

The cytotoxic ribonuclease onconase targets RNA interference (siRNA).

Onconase (Onc), a ribonuclease from oocytes of Northern Leopard frogs (Rana pipiens) is cytostatic and cytotoxic to a variety of tumor lines in vitro, inhibits growth of tumors in animal in vivo models and enhances sensitivity of tumor cells to a number of other cytotoxic agents with diverse mechanism of action. In Phase III clinical trials Onc demonstrated significant efficacy in patients with malignant mesothelioma that failed prior chemotherapy. We previously postulated that the antitumor activity of Onc and the observed synergisms with other antitumor modalities at least in part may be mediated by targeting RNA interference (RNAi). In the present study we observed that the silencing of the glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene in human lung adenocarcinoma A549 cells by siRNA was effectively prevented by Onc. While transfection of cells with GAPDH siRNA reduced expression of this protein by nearly 70%, the expression was restored in the cells exposed to 0.8 muM Onc for 48 or 72 h. The data thus provide evidence that one of the targets of Onc is siRNA, likely within the RNA-induced silencing complex (RISC). In light of the findings that microRNAs are involved in tumor pathogenesis as well as in enhancing cell resistance to anticancer therapy the present data may provide explanation for both, the antitumor Onc activity and its propensity to enhance effectiveness of cytotoxic drugs.

Cytostatic and cytotoxic properties of Amphinase: a novel cytotoxic ribonuclease from Rana pipiens oocytes.

Onconase (Onc), is a novel amphibian cytotoxic ribonuclease with antitumor activity, and is currently in a confirmatory phase III clinical trial for the treatment of malignant mesothelioma. It was recently reported that Rana pipiens oocytes contain still another ribonuclease, named Amphinase (Amph). Amph shows 38-40% amino acid sequence identity with onconase, presents as four variants varying between themselves from 87-99% in amino acid sequence identity and has a molecular mass approximately 13,000. In the present study we describe the effects of Amph on growth of several tumor cell lines. All four variants demonstrated cytostatic and cytotoxic activity against human promyelocytic HL-60-, Jurkat T-cell- and U-937 monocytic leukemia cells. The pattern of Amph activity to certain extent resembled that of Onc. Thus, cell proliferation was suppressed at 0.5-10.0 mug/ml (40-80 nM) Amph concentration with distinct accumulation of cells in G(1) phase of the cell cycle. In addition, the cells were undergoing apoptosis, which manifested by DNA fragmentation (presence of "sub-G1" cells, TUNEL-positivity), caspases and serine proteases activation as well as activation of transglutaminase. The cytostatic and cytotoxic effects of Amph required its ribonuclease activity: the enzymatically inactive Amph-2 having histidine at the active site alkylated was ineffective. The effectiveness and cell cycle specificity was generally similar for all four Amph variants and at the equimolar concentrations was somewhat more pronounced than that of Onc. The observed cytostatic and cytotoxic activity of Amph against tumor cell lines suggests that similar to Onc this cytotoxic ribonuclease may have antitumor activity and find an application in clinical oncology.

The interdependence between catalytic activity, conformational stability, and cytotoxicity of onconase.

Onconase (ONC) is a cytotoxic ribonuclease of the pancreatic ribonuclease A superfamily isolated from oocytes or early embryos of the Northern leopard frog (Rana pipiens). It shows anticancer activity and currently is in Phase IIIb clinical trial for unresectable malignant mesothelioma. We generated several variants of ONC possessing mutations in selected structural regions of the molecule that have altered ribonucleolytic activity and/or conformational stability. The relationship between the stability and ribonucleolytic activity of these variants and their cytostatic and cytotoxic properties was investigated on several tumor cell lines. Similar to ONC, all variants were inducing reproductive cell death detected by reduced clonogenicity. The surviving cells proliferated at reduced rates as reflected by diminished size of colonies and prolongation of G(0/1) phase of the cell cycle. Some cells were undergoing apoptosis. The cytotoxic and cytostatic effects of ONC and its variants were predominantly determined by their catalytic activity rather than by conformational stability.

Enzymatic and structural characterisation of amphinase, a novel cytotoxic ribonuclease from Rana pipiens oocytes.

Besides Onconase (ONC) and its V11/N20/R103-variant, oocytes of the Northern Leopard frog (Rana pipiens) contain another homologue of ribonuclease A, which we named Amphinase (Amph). Four variants (Amph-1-4) were isolated and sequenced, each 114 amino acid residues in length and N-glycosylated at two positions. Sequence identities (a) among the variants and (b) versus ONC are 86.8-99.1% and 38.2-40.0%, respectively. When compared with other amphibian ribonucleases, a typical pattern of cysteine residues is evident but the N-terminal pyroglutamate residue is replaced by a six-residue extension. Amph variants have relatively weak ribonucleolytic activity that is insensitive to human ribonuclease inhibitor protein (RI). Values of k(cat)/K(M) with hypersensitive fluorogenic substrates are 10(4) and 10(2)-fold lower than the maximum values exhibited by ribonuclease A and ONC, respectively, and there is little cytosine/uracil or adenine/guanine discrimination at the B(1) or B(2) subsites, respectively. Amph variants have cytotoxic activity toward A-253 carcinoma cells that requires intact ribonucleolytic activity. The glycan component has little or no influence over single-stranded RNA cleavage, RI evasion or cytotoxicity. The crystal structures of natural and recombinant Amph-2 (determined at 1.8 and 1.9 A resolution, respectively) reveal that the N terminus is unlikely to play a catalytic role (but an unusual alpha2-beta1 loop may do so) and the B(2) subsite is rudimentary. At the active site, structural features that may contribute to the enzyme's low ribonucleolytic activity are the fixture of Lys14 in an obstructive position, the accompanying ejection of Lys42, and a lack of constraints on the conformations of Lys42 and His107.

Cytotoxic ribonucleases and RNA interference (RNAi).

Several cytotoxic ribonucleases (CRs), homologs of the pancreatic RNase A, have been isolated from amphibian oocytes or embryos. Of them, onconase (Onc), the CR that shows antitumor properties and is in phase III clinical trials, was the most extensively researched. Degradation of tRNA by Onc internalized into cells that leads to inhibition of protein synthesis is considered the mechanism of its cytotoxicity. Several findings, however, cannot be explained by nonspecific decline in protein synthesis alone and suggest additional or alternative mechanism(s). We postulate therefore that miRNAs and/or RNA interference (RNAi) may also be targets of CRs. The following arguments support this postulate: (A) miRNAs and siRNAs appear to be unprotected by proteins and therefore, as tRNA, accessible and degradable by CRs; (B) Onc has preferred cleavage sites on tRNAs: their cleavage may generate segments of dsRNA that interfere with translation. Analogous to Dicer, thus, small RNAs with interfering properties may be generated by CRs within the cell; (C) CRs are abundant in oocytes and during embryonic development; their role there is unknown. Since cells undergo perpetual differentiation during embryogenesis it is likely that the function of CRs is to provide additional level of regulation of gene expression via the mechanisms listed in (A) and/or (B).

Entry into cells and selective degradation of tRNAs by a cytotoxic member of the RNase A family.

Onconase (P-30 protein), an enzyme in the ribonuclease A superfamily, exerts cytostatic, cytotoxic, and antiviral activity when added to the medium of growing mammalian cells. We find that onconase enters living mammalian cells and selectively cleaves tRNA with no detectable degradation of rRNA. The RNA specificity of onconase in vitro using reticulocyte lysate and purified RNA substrates indicates that proteins associated with rRNA protect the rRNA from the onconase ribonucleolytic action contributing to the cellular tRNA selectivity of onconase. The onconase-mediated tRNA degradation in cells appears to be accompanied by increased levels of tRNA turnover and induction of tRNA synthesis perhaps in response to the selective toxin-induced loss of tRNA. Degradation products of tRNA(3)(Lys), which acts as a primer for HIV-1 replication, were clearly detected in cells infected with HIV-1 and treated with sublethal concentrations of onconase. However, a new synthesis of tRNA(3)(Lys) also seemed to occur in these cells resulting in plateauing of the steady-state levels of this tRNA. We conclude that the degradation of tRNAs may be a primary factor in the cytotoxic activity of onconase.